Acessibilidade / Reportar erro

Microbial Profile and Endotoxin Levels in Primary Periodontal Lesions with Secondary Endodontic Involvement

Abstract

This study was carried out to investigate the microbial profile and endotoxin levels of endodontic-periodontal lesions of periodontal origin. Periodontal and endodontic samples were taken from periodontal pockets and necrotic root canals of 10 teeth with endodontic-periodontal lesions. Evidencing of 40 different bacterial species were determined in each endodontic and periodontal sample using the checkerboard DNA-DNA hybridization method and Kinetic chromogenic LAL assay was used for quantification of endotoxins. Fisher’s exact test correlated the bacterial species with the endodontic or periodontal microbiota. The endotoxin levels (EU/mL) found in samples of the root canal and periodontal pocket were compared by the Wilcoxon test (p<0.05). Bacteria and LPS units were found in 100% of the endodontic and periodontal samples. The species E. faecium, P. acnes, G. morbillorum, C. sputigena and L. buccalis were strongly correlated with the endodontic microbiota and P. nigrescens with the periodontal microbiota. P. intermedia, P. endodontalis and V. parvula were more prevalent in both endodontic and periodontal microbiots. The endotoxin levels in the periodontal pocket (89600 EU/mL) were significantly higher than in the root canal (2310 EU/mL). It was concluded that the microbiota present in the periodontal and endodontic tissues is similar, with a higher prevalence of species of the orange complex and a higher level of endotoxin in the periodontal pockets.

Key Words:
DNA probes; endodontics; lipopolysaccharides; microorganisms; periodontal disease

Resumo

Este estudo foi realizado para investigar o perfil microbiano e os níveis de endotoxina de lesões endoperiodontais de origem periodontal. Amostras periodontais e endodônticas foram obtidas de bolsas periodontais e canais radiculares necróticos de 10 dentes com lesões endoperiodontais. A investigação de 40 espécies bacterianas diferentes foram determinadas em cada amostra endodôntica e periodontal usando o método de hibridização de DNA-DNA (checkerboard) e o ensaio cinético cromogênico LAL foi usado para quantificação de endotoxinas. O teste exato de Fisher correlacionou as espécies bacterianas com a microbiota endodôntica ou periodontal. Os níveis de endotoxina (EU/mL) encontrados nas amostras do canal radicular e na bolsa periodontal foram comparados pelo teste de Wilcoxon (p<0,05). Bactérias e unidades de LPS foram encontradas em 100% das amostras endodônticas e periodontais. As espécies E. faecium, P. acnes, G. morbillorum, C. sputigena e L. buccalis foram fortemente correlacionadas com a microbiota endodôntica e P. nigrescens com a microbiota periodontal. P. intermedia, P. endodontalis e V. parvula foram mais prevalentes em ambas microbiotas endodôntica e periodontal. Os níveis de endotoxina na bolsa periodontal (89600 EU/mL) foram significativamente maiores do que no canal radicular (2310 EU/mL). Concluiu-se que a microbiota presente nos tecidos periodontal e endodôntico é semelhante, com maior prevalência de espécies do complexo laranja e maior nível de endotoxina nas bolsas periodontais.

Introduction

The periodontal and endodontic tissues have embryonic, anatomical and functional interrelationships. As the tooth and root development, communication pathways are created between the periodontium and pulp, such as dentinal tubules, lateral and accessory canals, and the apical foramen. Through these communications, it is believed that microorganisms and toxins may pervade structures serving as a source for infection in a two-way relationship, resulting in pathological entities known as endodontic-periodontal lesions 11 Jansson, L; Ehnevid, H; Lindskog, S; Blomlöf, L. Relationship between periapical and periodontal status. J Clin Periodontol 1993;20:117-123.,22 Rupf, S; Kannengiesser, S; Merte, K; Pfister, W; Sigusch, B; Eschrich K. Comparison of profiles of key periodontal pathogens in periodontium and endodontium. Endod Dent Traumatol 2000;16:269-275..

Endodontic-periodontal lesions are characterized by the association of endodontic and periodontal disease in the same tooth. Such infections are typically multi-species and interactions among different microorganisms may contribute to the development of endodontic and periodontal flora 33 Meng, HX. Periodontic-endodontic lesions. Ann Periodontol1999;4:84-90.. Studies that investigated teeth with periodontal and endodontic infection demonstrated that the microorganisms present in the root canals with advanced periodontal disease were similar to those found in the adjacent periodontal pockets (2,4-8). Furthermore, Didilescu et al. 99 Didilescu, AC; Rusu, D; Anghel, A; Nica, L; Iliescu, A; Greabu, M; et al. Investigation of six selected bacterial species in endo-periodontal lesions. Int Endod J 2012;45:282-293. investigated the association of six bacterial species in endodontic-periodontal lesions and found that the species Fusobacterium nucleatum, Capnocytophaga sputigena and Parviromona micra were more prevalent, suggesting that these species may play a role in the pathogenesis of these lesions.

Lipopolysaccharide (LPS), also known as endotoxin, is the major macromolecule found in the outer cell membrane of Gram-negative bacteria being released after its division or death. It is an important virulence factor which plays a role in endodontic and periodontal infections and its presence has been correlated with clinical symptomatology and bone resorption in pulpal and periapical lesions 1010 Gomes, BPFA; Endo, MS; Martinho, FC. Comparison of endotoxin levels found in primary and secondary endodontic infections. J Endod 2012;38:1082-1086.,1111 Cardoso, FG; Ferreira, NS; Martinho, FC; Nascimento, GG; Manhães, LR; Rocco, MA; et al. Correlation between volume of apical periodontitis determined by cone-beam computed tomography analysis and endotoxin levels found in primary root canal infection. J Endod 2015;41:1015-1019.. LPS is considered one of the most potent inflammatory cascade initiators because it can activate monocytes and macrophages to produce proinflammatory cytokines such as tumor necrosis factor alpha (TNF-a), interleukins (IL) -1, IL-6, IL -8, and IL-12 1212 Fujihara, M; Muroi, M; Tanamoto, KI; Suzuki, T; Azuma, H; Ikeda, H. Molecular mechanisms of macrophage activation and deactivation by lipopolysaccharide: roles of the receptor complex. Pharmacol Ther 2003;100:171-194..

Until now, there are few studies regarding bacterial community of endodontic-periodontal lesions in the literature (2,4-7,9) and, consequently, treatment protocols of these lesions are not well established in clinical practice. The qualitative and quantitative correlation of pathogens and endotoxins in the infection processes of endodontic-periodontal lesions may offer a better understanding of the disease and it is essential for the development of improved strategies for diagnosis and therapeutic intervention. Thus, the aim of the present study was to investigate the microbial profile by 40 different species and endotoxin levels of endodontic-periodontal lesions of periodontal origin.

Material and Methods

Patient Selection

Ten patients were selected among those seeking dental treatment at São José dos Campos Dental School. A detailed dental history was obtained from each patient. The study included subjects which presented teeth with pulp necrosis associated with periapical lesion, gingival bleeding and ≥6 mm periodontal pocket in more than one site. Pulp status was assessed through thermal vitality tests and cavity test. The periapical status was determined through the observation of clinical and radiographic signs, and symptoms such as tenderness to percussion and pain on palpation. Exclusion criteria were teeth with the pulp chamber exposed to the oral cavity, previous endodontic treatment, caries communicating to the pulp chamber, presence of cracks or fissures, calcifications and external resorption. The presence of cracks or fissures was assessed through transillumination, wedging and staining tests, followed by radiographic examination. Thus, the lesions were endodontic-periodontal lesions whose infection was probably of periodontal origin 1313 Simon, JHS; Glick, DH; Frank, AL. The relationship of endodontic-periodontic lesions. J Endod 2013;39:e41-e46.. In addition, were excluded patients who presented systemic diseases, those who had undergone periodontal treatment during the last 6 months prior to the study, smoking and antibiotic therapy during the last 6 months prior to the study. All subjects who agreed to participate in the study were informed about the nature and potential risks and signed a free informed consent form. Furthermore, the study was approved by the local Institute Review Board (CAAE: 30936714.8.0000.0077).

Sample Collection

All materials used in this study were treated with Co-gamma radiation (20 kGy for 6 h) for sterilization and elimination of preexisting endotoxins (EMBRARAD; Empresa Brasileira de Radiação, Cotia, SP, Brazil). Initially, the supragingival plaque was removed by rubbing a sterile gauze moistened in saline solution on all faces of the tooth crown and air jets were applied in order to keep the tooth surface dry. The periodontal sites to be sampled were isolated with cotton rolls in order to avoid contamination by saliva.

Periodontal samples were first collected as follows: four pyrogen-free paper points #30 (Dentsply, Petrópolis, RJ, Brazil) were inserted into the deepest periodontal pocket of the teeth, one at a time, where they remained for 1 min. The first paper point was transferred to an eppendorf tube and stored at -20 °C until the limulus amebocyte lysate (LAL) assay. The last three paper points were immediately transferred to one eppendorf tube containing 1 mL Tris-EDTA buffer (10 mmol/L Tris-HCl, 1 mmol/L EDTA, pH=7.6). Then, 1 mL of 0.5 mol/L NaOH was added to each tube, and samples were frozen at -20º C until they were processed for checkerboard DNA-DNA analyses.

Subsequently, endodontic samples were collected under absolute isolation with a rubber dam. The operative field (outer surface of crown, clamp, rubber dam and frame) was disinfected in three steps: first with 30% hydrogen peroxide, second with 5.25% sodium hypochlorite (NaOCl) and third with 5% sodium thiosulfate. The access to the pulp chamber was made without the use of water spray but under manual irrigation with sterile/apyrogenic saline solution and by using sterile/apyrogenic high-speed diamond bur. All procedures were performed aseptically. Four paper points #15 (Dentsply, Petrópolis, RJ, Brazil) were consecutively introduced into the full length of the canal, which was determined radiographically. The storage method followed the same as periodontal samples.

Microbiological Assay: Checkerboard DNA-DNA

Counts of 40 different bacterial species (Table 1) were determined in each endodontic and periodontal sample, using the checkerboard DNA-DNA hybridization technique. DNA extraction was performed with the Qlaamp DNA kit (QIAGEN, Chatsworth, CA, USA) according to the manufacturer’s instructions. Briefly, each sample suspension containing free DNA was deposited in the slits of a Minislot 30® (Immunetics, Cambridge, MA, USA) containing a positively charged nylon membrane (15 x 15 cm) (Amersham Biosciences, Chicago, IL, USA), where the DNA was fixed by oven heating at 120 °C for 20 min. The last two channels of the Minislot 30® were reserved for the placement of the controls, containing a mixture of species of microorganisms that were investigated by DNA probes at concentrations 105 and 106 bacterial cells. DNA probes specific for the 40 species were made using Random Primer Digoxigenin Labeling kit (Boehringer Mannheim, Indianapolis, IN, USA), as described by Feinberg and Volgelstein 1414 Feinberg, AP; Vogelstein S. A technique for radio-labeling DNA fragments to high specific activity. Anal Biochem 1984;137:266-267.. Prior to their use, the probes were tested with a control mixture containing the investigated species, at a concentration of 104 bacterial cells. Their concentrations were adjusted such that the signal intensity of all probes became similar.

Table 1
DNA probes of bacterial strains

After fixation of DNA in the membrane, the DNA probes were hybridized perpendicular to the lines containing the bacterial DNA using a Miniblotter 45® device (Immunetics, Cambridge, MA, USA). Bound probes were detected using anti-digoxigenin antibody (Roche Diagnostics GmbH, Mannheim, Germany) conjugated to alkaline phosphatase (Boehringer, Mannheim, Germany), at a dilution of 1/25000, and by chemiluminescence using CDP-Star Detection Reagent® (Amershan Biosciences UK Limited, Buckinghamshire, UK). The membranes were placed in cassette under a Kodak® X-OMAT radiographic film (Kodak Brasileira Com. e Ind. Ltda, São José dos Campos, SP, Brazil) for approximately 40 min, and the films were revealed shortly thereafter. Each signal produced by a given probe in the root canals sample was compared with the signal produced by the same probe in the two controls containing 105 and 106 bacterial cells.

Quantification of Endotoxins: Kinetic Chromogenic LAL ASSAY

The method used for measuring the endotoxin levels has been previously published 1111 Cardoso, FG; Ferreira, NS; Martinho, FC; Nascimento, GG; Manhães, LR; Rocco, MA; et al. Correlation between volume of apical periodontitis determined by cone-beam computed tomography analysis and endotoxin levels found in primary root canal infection. J Endod 2015;41:1015-1019.. First, 1 mL of apyrogenic water was added to each tube containing the paper point and the endotoxin extraction was performed by mechanical shaking in vortex for 60 s. Subsequently, endotoxin suspensions were serially diluted to 10-1. Kinetic chromogenic limulus amebocyte lysate assay (Lonza, Walkersville, MD, USA) was used for quantification of endotoxins. As a parameter for calculating the amount of endotoxins in periodontal and endodontic samples, a standard curve was plotted by using endotoxins supplied in the kit with a known concentration (50 EU/mL) and their dilutions (0.005, 0.05, 0.5, and 5 EU/mL) according to the manufacturer’s instructions. Endotoxin from Escherichia coli was used as standard. A positive control (periodontal and endodontic samples contaminated with a known amount of endotoxin - 10 EU/mL) was included for each sample to determine the presence or absence of interfering agents. A 96-well apyrogenic plate (Easypath, São Paulo, SP, Brazil) was used in a heating block at 37° C and maintained at this temperature throughout the assay. For the test, 100 mL of apyrogenic water (blank), 5 standard endotoxin solutions (0.005-50 EU/mL), periodontal and endodontic samples, and positive controls (each periodontal and endodontic sample contaminated with a known concentration of endotoxin - 10 EU/mL) were added to the 96-well apyrogenic plate. The tests were carried out in quadruplicate. The plate was incubated at 37±1 °C for 10 min in a KineticQCL reader, which was coupled to a computer with the WinKQCL software (Lonza). Then, 100 mL of the chromogenic reagent was added to each well. As soon as the kinetic test started, absorbance at 405 nm was read in each microplate well and automatically calculated the log/log linear correlation between reaction time of each standard solution and corresponding endotoxin concentration.

Statistical Analysis

Investigation of 40 bacterial species in each endodontic and periodontal sample was expressed in mean prevalence and levels of each species in each sample. Prevalence was determined based on the proportions of endodontic and periodontal sample colonized by each bacterial species at counts <105, 105, 105-106 and 106. Fisher’s exact test was used to correlate the bacterial species with the endodontic or periodontal microbiota. The endotoxin levels (EU/mL) found in the root canal and periodontal pocket samples were compared by the Wilcoxon test. The level of significance was set at 5%.

Results

Prevalence and levels of each bacterial species in endodontic and periodontal samples are presented in Figure 1 and Figure 2, respectively. Microorganisms were found in 100% of the samples by checkerboard DNA-DNA hybridization. Among 40 bacterial species evaluated, six species, including S. noxia, S. gordonii, F. nucleatum ssp polymorphum, S. anginosus, E. saburreum and A. actinomycetemcomitans, were not detected in any endodontic sample. The most prevalent species at this site were P. endodontalis (80%), L. buccalis (80%), C. sputigena (70%), E. faecium (70%), A. oris (70%), V. parvula (70%), P. micra (70%), P. intermedia (60%), G. morbillorum (60%) and E. nodatum (60%) (Fig 1).

Figure 1
The mean prevalence (% endodontic sample colonized) and levels (<105, 105, 105-106 and 106) of each bacterial species in samples of the root canal of endodontic-periodontal lesions. The total length of each bar indicates percentage of positive samples. Different colors inside each bar indicate percentage of samples containing different levels of bacterial DNA.

Figure 2
The mean prevalence (% periodontal sample colonized) and levels (<105, 105, 105-106 and 106) of each bacterial species in samples of the periodontal pocket of endodontic-periodontal lesions. The total length of each bar indicates percentage of positive samples. Different colors inside each bar indicate percentage of samples containing different levels of bacterial DNA.

Regarding the periodontal samples, 14 microorganisms were not found: C. gracilis, C. sputigena, G. morbillorum, E. corrodens, P. acnes, S. noxia, C. gingivalis, N. mucosa, A. odontolyticus, E. faecium, C. ochracea, S. sanguinis, E. saburreum and A. actinomycetemcomitans. The most prevalent bacterial species in these samples were: P. nigrescens (70%), P. intermedia (50%), V. parvula (50%), F. nucleatum ssp vincentii (50%), P. gingivalis (40%), P. endodontalis (40%), F. nucleatum (40%) and E. nodatum (40%) (Fig. 2).

According to Fisher’s exact test, the species E. faecium (p=0.0031), P. acnes (p=0.0325), G. morbillorum (p=0.0108), C. sputigena (p=0.0031) and L. buccalis (p=0.0055) were strongly correlated with the endodontic microbiota. The species P. nigrescens was strongly correlated with the periodontal microbiota (p=0.0198). Although P. intermedia (p=0.75), P. endodontalis (p=0.34) and V. parvula (p=0.34) presented a weak correlation with both endodontic and periodontal microbiots, these bacteria were the most prevalent in both sites.

LPS units were found in all samples, both periodontal and endodontic. The endotoxin levels (EU/mL) obtained in the periodontal pocket samples (89600 EU/mL) were significantly higher compared with the levels obtained in the root canal samples (2310 EU/mL) (p=0.002). Figure 3 shows the minimum, maximum and median values of endotoxins (EU/mL) found in the root canal and periodontal pocket.

Figure 3
Median, maximum and minimum values of endotoxin levels (EU/mL) found in the root canal and periodontal pocket of endodontic-periodontal lesions.

Discussion

The effectiveness of the treatment of infectious diseases depends not only on the antimicrobial potential of the therapeutic strategies, but also on the susceptibility of the microbial species involved. The knowledge of the microbiological profile and endotoxin levels in endodontic-periodontal lesions can contribute to a better understanding of the pathogenesis of the disease, as well as to direct the therapeutic conducts. In addition, the use of antibiotics has been increasingly considered as an option to treat periodontal disease and the microbiological diagnosis may direct the choice of a specific antibiotic agent, also reducing the possibility of developing bacterial resistance 1515 Shaddox, LM; Walker, C. Microbial testing in periodontics: value, limitations and future directions. Periodontol2000;50:25-38.. Thus, the main objective of this study was to investigate and identify the microbiological profile of endodontic-periodontal lesions of periodontal origin by the checkerboard DNA-DNA hybridization method, as well as to quantify and correlate the endotoxin levels by the LAL assay. The checkerboard DNA-DNA hybridization is a rapid and sensitive molecular identification technique that permits the determination of the presence of multiple bacterial species in very large numbers of samples containing complex mixtures of microorganisms 1616 Socransky, SS; Haffajee, AD; Smith, C; Martin, L; Haffajee, JA; Uzel, NG; et al. Use of checkerboard DNA-DNA hybridization to study complex microbial ecosystems. Oral Microbiol Immunol 2004;19:352-362.. Regarding its limitations, checkerboard technique can only detect species for which the DNA probes have been prepared, in addition to not detecting microorganisms that are below the detection limits of the method (103 to 104 cells) 1616 Socransky, SS; Haffajee, AD; Smith, C; Martin, L; Haffajee, JA; Uzel, NG; et al. Use of checkerboard DNA-DNA hybridization to study complex microbial ecosystems. Oral Microbiol Immunol 2004;19:352-362.. The method used for measuring the endotoxin levels has been previously published 1010 Gomes, BPFA; Endo, MS; Martinho, FC. Comparison of endotoxin levels found in primary and secondary endodontic infections. J Endod 2012;38:1082-1086.,1111 Cardoso, FG; Ferreira, NS; Martinho, FC; Nascimento, GG; Manhães, LR; Rocco, MA; et al. Correlation between volume of apical periodontitis determined by cone-beam computed tomography analysis and endotoxin levels found in primary root canal infection. J Endod 2015;41:1015-1019. and has high sensitivity and precision 171+ Martinho, FC; Chiesa, WM; Zaia, AA; Ferraz, CC; Almeida, JF; Souza-Filho, FJ; et al. Comparison of endotoxin levels in previous studies on primary endodontic infections. J Endod 2011;37:163-167.. The 40 species investigated in this study were selected because of their association with endodontic/periodontal infections or their presence in other oral infections and saliva 1818 Gomes, BP; Pinheiro, ET; Gadê-Neto, CR; Sousa, EL; Ferraz, CC; Zaia, AA; et al. Microbiological examination of infected dental root canals. Oral Microbiol Immunol 2004;19:71-76.,1919 Haffajee, AD. Clinical and microbiological features of subjects with adult periodontitis who responded poorly to scaling and root planing. J Clin Periodontol 1997;24:767-776.,2020 Socransky, SS; Haffajee, AD; Cugini, MA; Smith, C; Kent Jr, RL. Microbial complexes in subgingival plaque. J Clin Periodontol 1998;25:134-144.,2121 Jung, IY; Choi, BK; Kum, KY; Roh, BD; Lee, SJ; Lee, CY; et al. Molecular epidemiology and association of putative pathogens in root canal infection. J Endod 2000;26:599-604..

The microbiota of the root canal in endodontic-periodontal lesions was similar to that found in the periodontal pocket, suggesting a pathway of infection between the pulp and periodontal tissues, particularly through the apical foramen, accessory canals and/or dentinal tubules exposed to the buccal environment, corroborating previous studies 22 Rupf, S; Kannengiesser, S; Merte, K; Pfister, W; Sigusch, B; Eschrich K. Comparison of profiles of key periodontal pathogens in periodontium and endodontium. Endod Dent Traumatol 2000;16:269-275.,44 Kipioti, A; Nakou, M; Legakis, N; Mitsis F. Microbiological findings of infected root canals and adjacent periodontal pockets in teeth with advanced periodontitis. Oral Surgery, Oral Med Oral Pathol 1984;58:213-220.,55 Kobayashi, T; Hayashi, A; Yoshikawa, R; Okuda, K; Hara, K. The microbial flora from root canals and periodontal pockets of non-vital teeth associated with advanced periodontitis. Int Endod J1990;23:100-106.,66 Li, H; Guan, R; Sun J; Hou, B. Bacteria community study of combined periodontal-endodontic lesions using denaturing gradient gel electrophoresis and sequencing analysis. J Periodontol 2014;85:1442-1449.,77 Gomes, BPFA; Berber, VB; Kokaras, AS; Chen, T; Paster, BJ. Microbiomes of endodontic-periodontal lesions before and after chemomechanical preparation. J Endod 2015;41:1975-1984.,88 Solomon, C; Chalfin, H; Kellert, M; Weseley, P. The endodontic-periodontal lesion: a rational approach to treatment. J Am Dent Assoc 1995;126:473-479.. Thus, the infected periodontal pocket was probably the main source of root canal infection in these cases of endoperiodontal lesions. The periodontal origin of the lesions was diagnosed because there was no evidence of pulpal aggression/infection via the dental crown, but rather a deep periodontal pocket and bone resorption progressing apically 1313 Simon, JHS; Glick, DH; Frank, AL. The relationship of endodontic-periodontic lesions. J Endod 2013;39:e41-e46.. The most prevalent species in the root canal samples were P. endodontalis (80%), L. buccalis (80%), C. sputigena (70%), E. faecium (70%), A. oris (70%), V. parvula (70%), P. micra (70%), P. intermedia (60%), G. morbillorum (60%) and E. nodatum (60%), all of them strict or facultative anaerobic bacteria. Other studies using culture-based methods also reported predominantly anaerobic polymicrobial flora in root canals of teeth with associated periodontal disease 44 Kipioti, A; Nakou, M; Legakis, N; Mitsis F. Microbiological findings of infected root canals and adjacent periodontal pockets in teeth with advanced periodontitis. Oral Surgery, Oral Med Oral Pathol 1984;58:213-220.,55 Kobayashi, T; Hayashi, A; Yoshikawa, R; Okuda, K; Hara, K. The microbial flora from root canals and periodontal pockets of non-vital teeth associated with advanced periodontitis. Int Endod J1990;23:100-106.. Higher prevalence of P. micra was also reported by Hong et al. 66 Li, H; Guan, R; Sun J; Hou, B. Bacteria community study of combined periodontal-endodontic lesions using denaturing gradient gel electrophoresis and sequencing analysis. J Periodontol 2014;85:1442-1449. when studying the intracanal and periodontal bacterial community in teeth with combined endodontic-periodontal lesions, in addition to Porphyromonas gingivalis and Tannerella forsythia. The species E. faecium, P. acnes, G. morbillorum, C. sputigena and L. buccalis were strongly correlated with the endodontic microbiota in the present study, and were rarely detected in samples from the periodontal pocket, indicating that such bacteria are more specifically associated with endodontic microflora.

The most prevalent species in the periodontal samples were P. nigrescens (70%), P. intermedia (50%), V. parvula (50%), F. nucleatum ssp vincentii (50%), P. gingivalis (40%), P. endodontalis (40%), F. nucleatum (40%) and E. nodatum (40%), all of them strict anaerobic bacteria. P. nigrescens was the only bacteria strongly correlated with the periodontal microbiota. Thus, there was a high prevalence of microorganisms of the orange complex in the periodontal pockets, known as the one with the greatest pathogenicity alongside the red complex 2020 Socransky, SS; Haffajee, AD; Cugini, MA; Smith, C; Kent Jr, RL. Microbial complexes in subgingival plaque. J Clin Periodontol 1998;25:134-144.. However, in addition to its relationship with periodontal pathogenicity, high incidence of this complex has also been associated with endodontic infections 2222 Craig, BJ; Falkler, WA. Bacteria in the apical 5 mm of infected root canals. J Endod 1991;17:380-383.,2323 Lana, MA; Ribeiro-Sobrinho, AP; Stehling, R; Garcia, GD; Silva, BK; Hamdan, JS; et al. Microorganisms isolated from root canals presenting necrotic pulp and their drug susceptibility in vitro. Oral Microbiol Immunol 2001;16:100-105.,2424 Siqueira, JF; Rôças, IN; Alves, FRF; Santos, KRN. Selected endodontic pathogens in the apical third of infected root canals: a molecular investigation. J Endod 2004;30:638-643.. Bacteria of the orange complex as, P. micra, P. intermedia and E. nodatum, were also prevalent in the root canal samples. Although they presented a weak association with both endodontic and periodontal microbiots, P. intermedia, P. endodontalis and V. parvula were predominant in both sites and may play a role in the pathogenesis of endoperiodontal lesions. Didilescu et al. 99 Didilescu, AC; Rusu, D; Anghel, A; Nica, L; Iliescu, A; Greabu, M; et al. Investigation of six selected bacterial species in endo-periodontal lesions. Int Endod J 2012;45:282-293. found a correlation of endodontic-periodontal infections with P. micra, F. nucleatum and C. sputigena, however in their study were analyzed cases with both primary and secondary endodontic infections. In the present investigation, these microorganisms were also found in both tissues, especially P. micra, but this correlation was not statistically significant.

Endodontic-periodontal lesions are characterized by a great bone loss 33 Meng, HX. Periodontic-endodontic lesions. Ann Periodontol1999;4:84-90.,88 Solomon, C; Chalfin, H; Kellert, M; Weseley, P. The endodontic-periodontal lesion: a rational approach to treatment. J Am Dent Assoc 1995;126:473-479., what relate them to Gram-negative microorganisms and their endotoxins or LPS. In endodontics, LPS has been strongly correlated to pain and periapical bone resorption 1010 Gomes, BPFA; Endo, MS; Martinho, FC. Comparison of endotoxin levels found in primary and secondary endodontic infections. J Endod 2012;38:1082-1086.,1111 Cardoso, FG; Ferreira, NS; Martinho, FC; Nascimento, GG; Manhães, LR; Rocco, MA; et al. Correlation between volume of apical periodontitis determined by cone-beam computed tomography analysis and endotoxin levels found in primary root canal infection. J Endod 2015;41:1015-1019.. In the present study, the most prevalent bacteria in the periodontal pockets were Gram-negative bacteria, with the exception of E. nodatum. In the root canal samples, predominantly Gram-negative bacteria such as P. endodontalis, L. buccalis, C. sputigena, V. parvula and P. intermedia were also detected. The endotoxin level in the periodontal pocket (89600 EU/mL) was significantly higher in comparison with the root canal (2310 EU/mL) and this difference can be explained by the microbial load, specifically Gram-negative species, which was higher in the periodontium compared with the root canal, consistent with previous studies 22 Rupf, S; Kannengiesser, S; Merte, K; Pfister, W; Sigusch, B; Eschrich K. Comparison of profiles of key periodontal pathogens in periodontium and endodontium. Endod Dent Traumatol 2000;16:269-275.,99 Didilescu, AC; Rusu, D; Anghel, A; Nica, L; Iliescu, A; Greabu, M; et al. Investigation of six selected bacterial species in endo-periodontal lesions. Int Endod J 2012;45:282-293.. Duque et al. 2525 Duque, TM; Prado, M; Herrera, DR; Gomes, BPFA. Periodontal and endodontic infectious/inflammatory profile in primary periodontal lesions with secondary endodontic involvement after a calcium hydroxide-based intracanal medication. Clin Oral Investig 2018:1-11., through a clinical study, also found a higher level of LPS in the periodontal pockets than in the root canals in teeth with primary periodontal lesion and secondary endodontic involvement. The median value of 2310 EU/mL obtained from root canals was high compared with other studies evaluating endotoxin levels in root canals with primary endodontic infections, whose levels ranged from 7.49-198 EU/mL 1010 Gomes, BPFA; Endo, MS; Martinho, FC. Comparison of endotoxin levels found in primary and secondary endodontic infections. J Endod 2012;38:1082-1086.,1111 Cardoso, FG; Ferreira, NS; Martinho, FC; Nascimento, GG; Manhães, LR; Rocco, MA; et al. Correlation between volume of apical periodontitis determined by cone-beam computed tomography analysis and endotoxin levels found in primary root canal infection. J Endod 2015;41:1015-1019.,171+ Martinho, FC; Chiesa, WM; Zaia, AA; Ferraz, CC; Almeida, JF; Souza-Filho, FJ; et al. Comparison of endotoxin levels in previous studies on primary endodontic infections. J Endod 2011;37:163-167.. This may be due to the methodological differences among works, mainly in relation to the sample collection method. Higher values obtained in this study can be explained by the fact that in our cases the periodontal pocket was already in communication with the apical foramen, which probably led to an increase in the number of microorganisms and LPS in root canals.

In conclusion, it was demonstrated that the microbiota present in the periodontal and endodontic tissues of teeth with endodontic-periodontal lesion is similar, with a higher prevalence of species of the orange complex, suggesting that the periodontal pocket may be an important source of root canal infection. The species E. faecium, P. acnes, G. morbillorum, C. sputigena and L. buccalis were strongly correlated with the endodontic microbiota and P. nigrescens with the periodontal microbiota. The species P. intermedia, P. endodontalis and V. parvula were predominant in both samples of the root canal and periodontal pocket and may play a role in the pathogenesis of endodontic-periodontal lesions. However, it is necessary to define the specific role played by these pathogens in this type of lesion and thus to determine the best therapeutic measures for its eradication. In addition, further studies evaluating all microorganisms by using DNA sequencing should be performed to evaluate other potential pathogens related to this type of lesion. The endotoxin levels found in the periodontal pocket was higher compared with the root canal.

References

  • 1
    Jansson, L; Ehnevid, H; Lindskog, S; Blomlöf, L. Relationship between periapical and periodontal status. J Clin Periodontol 1993;20:117-123.
  • 2
    Rupf, S; Kannengiesser, S; Merte, K; Pfister, W; Sigusch, B; Eschrich K. Comparison of profiles of key periodontal pathogens in periodontium and endodontium. Endod Dent Traumatol 2000;16:269-275.
  • 3
    Meng, HX. Periodontic-endodontic lesions. Ann Periodontol1999;4:84-90.
  • 4
    Kipioti, A; Nakou, M; Legakis, N; Mitsis F. Microbiological findings of infected root canals and adjacent periodontal pockets in teeth with advanced periodontitis. Oral Surgery, Oral Med Oral Pathol 1984;58:213-220.
  • 5
    Kobayashi, T; Hayashi, A; Yoshikawa, R; Okuda, K; Hara, K. The microbial flora from root canals and periodontal pockets of non-vital teeth associated with advanced periodontitis. Int Endod J1990;23:100-106.
  • 6
    Li, H; Guan, R; Sun J; Hou, B. Bacteria community study of combined periodontal-endodontic lesions using denaturing gradient gel electrophoresis and sequencing analysis. J Periodontol 2014;85:1442-1449.
  • 7
    Gomes, BPFA; Berber, VB; Kokaras, AS; Chen, T; Paster, BJ. Microbiomes of endodontic-periodontal lesions before and after chemomechanical preparation. J Endod 2015;41:1975-1984.
  • 8
    Solomon, C; Chalfin, H; Kellert, M; Weseley, P. The endodontic-periodontal lesion: a rational approach to treatment. J Am Dent Assoc 1995;126:473-479.
  • 9
    Didilescu, AC; Rusu, D; Anghel, A; Nica, L; Iliescu, A; Greabu, M; et al. Investigation of six selected bacterial species in endo-periodontal lesions. Int Endod J 2012;45:282-293.
  • 10
    Gomes, BPFA; Endo, MS; Martinho, FC. Comparison of endotoxin levels found in primary and secondary endodontic infections. J Endod 2012;38:1082-1086.
  • 11
    Cardoso, FG; Ferreira, NS; Martinho, FC; Nascimento, GG; Manhães, LR; Rocco, MA; et al. Correlation between volume of apical periodontitis determined by cone-beam computed tomography analysis and endotoxin levels found in primary root canal infection. J Endod 2015;41:1015-1019.
  • 12
    Fujihara, M; Muroi, M; Tanamoto, KI; Suzuki, T; Azuma, H; Ikeda, H. Molecular mechanisms of macrophage activation and deactivation by lipopolysaccharide: roles of the receptor complex. Pharmacol Ther 2003;100:171-194.
  • 13
    Simon, JHS; Glick, DH; Frank, AL. The relationship of endodontic-periodontic lesions. J Endod 2013;39:e41-e46.
  • 14
    Feinberg, AP; Vogelstein S. A technique for radio-labeling DNA fragments to high specific activity. Anal Biochem 1984;137:266-267.
  • 15
    Shaddox, LM; Walker, C. Microbial testing in periodontics: value, limitations and future directions. Periodontol2000;50:25-38.
  • 16
    Socransky, SS; Haffajee, AD; Smith, C; Martin, L; Haffajee, JA; Uzel, NG; et al. Use of checkerboard DNA-DNA hybridization to study complex microbial ecosystems. Oral Microbiol Immunol 2004;19:352-362.
  • 1+
    Martinho, FC; Chiesa, WM; Zaia, AA; Ferraz, CC; Almeida, JF; Souza-Filho, FJ; et al. Comparison of endotoxin levels in previous studies on primary endodontic infections. J Endod 2011;37:163-167.
  • 18
    Gomes, BP; Pinheiro, ET; Gadê-Neto, CR; Sousa, EL; Ferraz, CC; Zaia, AA; et al. Microbiological examination of infected dental root canals. Oral Microbiol Immunol 2004;19:71-76.
  • 19
    Haffajee, AD. Clinical and microbiological features of subjects with adult periodontitis who responded poorly to scaling and root planing. J Clin Periodontol 1997;24:767-776.
  • 20
    Socransky, SS; Haffajee, AD; Cugini, MA; Smith, C; Kent Jr, RL. Microbial complexes in subgingival plaque. J Clin Periodontol 1998;25:134-144.
  • 21
    Jung, IY; Choi, BK; Kum, KY; Roh, BD; Lee, SJ; Lee, CY; et al. Molecular epidemiology and association of putative pathogens in root canal infection. J Endod 2000;26:599-604.
  • 22
    Craig, BJ; Falkler, WA. Bacteria in the apical 5 mm of infected root canals. J Endod 1991;17:380-383.
  • 23
    Lana, MA; Ribeiro-Sobrinho, AP; Stehling, R; Garcia, GD; Silva, BK; Hamdan, JS; et al. Microorganisms isolated from root canals presenting necrotic pulp and their drug susceptibility in vitro. Oral Microbiol Immunol 2001;16:100-105.
  • 24
    Siqueira, JF; Rôças, IN; Alves, FRF; Santos, KRN. Selected endodontic pathogens in the apical third of infected root canals: a molecular investigation. J Endod 2004;30:638-643.
  • 25
    Duque, TM; Prado, M; Herrera, DR; Gomes, BPFA. Periodontal and endodontic infectious/inflammatory profile in primary periodontal lesions with secondary endodontic involvement after a calcium hydroxide-based intracanal medication. Clin Oral Investig 2018:1-11.

Publication Dates

  • Publication in this collection
    22 July 2019
  • Date of issue
    Jul-Aug 2019

History

  • Received
    21 Oct 2018
  • Accepted
    28 Feb 2019
Fundação Odontológica de Ribeirão Preto Av. do Café, S/N, 14040-904 Ribeirão Preto SP Brasil, Tel.: (55 16) 3602-3982, Fax: (55 16) 3633-0999 - Ribeirão Preto - SP - Brazil
E-mail: bdj@forp.usp.br